EU HCD TG WORKPROGRAMME 2008
14-Dec-09
EFDA WORKPROGRAMME 2010
Plasma Wall Interaction
TASK AGREEMENT
WP10-PWI
(covering WP10-PWI-01, WP10-PWI-02, WP10-PWI-03, WP10-PWI-04, WP10-PWI-05, WP10-PWI-06, WP10-PWI-07. WP10-PWI-TFL)
Between:The EFDA Leaderand the following Associates
- Belgium_ERM-KMS
- ENEA_CNR
- KIT
- Belgium_SCK-CEN
- ENEA_Frascati
- Latvia
- CCFE
- FOM_Rijnhuizen
- MEdC
- CEA
- FZJ
- MHST
- CIEMAT
- IPP
- OEAW
- CRPP
- IPP-CR
- TEKES
- Cyprus
- IPPLM
- VR
- DCU_Ireland
- IST
Start date:
01. Jan 2010
EFDA Responsible Officer:
Roman Zagorski
Tel.:
+49 89 3299 4314
E-mail:
Association:
Signature:
Date:
TABLE OF CONTENTS
Summary: WP10-PWI (Priority Support) 3
Chapter 1: Fuel retention as a function of wall materials foreseen for ITER8
Chapter 2: Exploration of fuel removal methods compatible with retention in mixed materials and metals, including beryllium25
Chapter 3: Dust generation and characterization in different devices, including the impact of fuel removal methods on dust production43
Chapter 4: Erosion, transport and deposition of low-Z wall materials60
Chapter 5: Development of the PWI basis in support of integrated high-Z scenarios for ITER. Demonstration of liquid plasma-facing components83
Chapter 6: Determination of expected alloys and compounds in ITER relevant conditions and their influence on PWI processes and fuel retention110
Chapter 7: Mitigation of disruptions and investigation of ELM and inter-ELM heat loads133
Chapter 8: PWI TF Leadership152
Summary: WP10-PWI (Priority Support)
Task
Association
Start date
End date
Priority Support (ppy)
Manpower (k€)
EU 8.2a contribution 20%
Hardware (k€)
EU 8.2b contribution 40%
EU contribution total (k€)
WP10-PWI-02
Belgium_ERM-KMS
01. Jan 2010
0.40
42.588
8.518
10.000
4.000
12.518
Total
0.40
42.588
8.518
10.000
4.000
12.518
WP10-PWI-05
Belgium_SCK-CEN
01. Jan 2010
0.70
145.852
29.170
35.000
14.000
43.170
Total
0.70
145.852
29.170
35.000
14.000
43.170
WP10-PWI-02
CCFE
01. Jan 2010
0.25
36.380
7.276
0.000
0.000
7.276
Total
0.25
36.380
7.276
0.000
0.000
7.276
WP10-PWI-01
CEA
01. Jan 2010
0.60
98.400
19.680
0.000
0.000
19.680
WP10-PWI-02
CEA
01. Jan 2010
0.60
63.000
12.600
0.000
0.000
12.600
WP10-PWI-03
CEA
01. Jan 2010
0.50
52.500
10.500
10.000
4.000
14.500
WP10-PWI-04
CEA
01. Jan 2010
0.65
77.550
15.510
35.000
14.000
29.510
WP10-PWI-07
CEA
01. Jan 2010
0.50
68.000
13.600
10.000
4.000
17.600
WP10-PWI-TFL
CEA
01. Jan 2010
0.50
82.000
16.400
0.000
0.000
16.400
Total
3.35
441.450
88.290
55.000
22.000
110.290
WP10-PWI-02
CIEMAT
01. Jan 2010
0.30
27.000
5.400
0.000
0.000
5.400
WP10-PWI-04
CIEMAT
01. Jan 2010
0.20
18.000
3.600
0.000
0.000
3.600
Total
0.50
45.000
9.000
0.000
0.000
9.000
WP10-PWI-05
ENEA_CNR
01. Jan 2010
0.35
29.120
5.824
0.000
0.000
5.824
Total
0.35
29.120
5.824
0.000
0.000
5.824
WP10-PWI-05
ENEA_Frascati
01. Jan 2010
1.10
154.529
30.906
25.000
10.000
40.906
Total
1.10
154.529
30.906
25.000
10.000
40.906
WP10-PWI-01
FOM_Rijnhuizen
01. Jan 2010
0.40
59.600
11.920
0.000
0.000
11.920
WP10-PWI-04
FOM_Rijnhuizen
01. Jan 2010
0.35
52.150
10.430
0.000
0.000
10.430
WP10-PWI-05
FOM_Rijnhuizen
01. Jan 2010
0.40
59.600
11.920
40.000
16.000
27.920
WP10-PWI-06
FOM_Rijnhuizen
01. Jan 2010
0.20
29.800
5.960
0.000
0.000
5.960
WP10-PWI-07
FOM_Rijnhuizen
01. Jan 2010
0.30
44.700
8.940
30.000
12.000
20.940
Total
1.65
245.850
49.170
70.000
28.000
77.170
WP10-PWI-01
FZJ
01. Jan 2010
0.60
63.087
12.618
5.000
2.000
14.618
WP10-PWI-02
FZJ
01. Jan 2010
0.30
40.560
8.112
0.000
0.000
8.112
WP10-PWI-03
FZJ
01. Jan 2010
0.25
27.789
5.558
7.000
2.800
8.358
WP10-PWI-04
FZJ
01. Jan 2010
1.20
136.830
27.366
20.000
8.000
35.366
WP10-PWI-05
FZJ
01. Jan 2010
0.70
69.910
13.982
5.000
2.000
15.982
WP10-PWI-06
FZJ
01. Jan 2010
0.60
81.120
16.224
0.000
0.000
16.224
WP10-PWI-07
FZJ
01. Jan 2010
1.00
113.059
22.612
30.000
12.000
34.612
Total
4.65
532.355
106.471
67.000
26.800
133.271
WP10-PWI-01
IPP
01. Jan 2010
0.80
89.000
17.800
0.000
0.000
17.800
WP10-PWI-02
IPP
01. Jan 2010
0.20
24.000
4.800
0.000
0.000
4.800
WP10-PWI-03
IPP
01. Jan 2010
0.30
36.000
7.200
10.000
4.000
11.200
WP10-PWI-04
IPP
01. Jan 2010
0.60
64.650
12.930
0.000
0.000
12.930
WP10-PWI-05
IPP
01. Jan 2010
0.60
63.600
12.720
3.000
1.200
13.920
WP10-PWI-06
IPP
01. Jan 2010
0.90
91.500
18.300
25.000
10.000
28.300
WP10-PWI-07
IPP
01. Jan 2010
0.95
114.000
22.800
0.000
0.000
22.800
WP10-PWI-TFL
IPP
01. Jan 2010
0.50
60.000
12.000
0.000
0.000
12.000
Total
4.85
542.750
108.550
38.000
15.200
123.750
WP10-PWI-02
IPPLM
01. Jan 2010
0.15
3.236
0.647
0.000
0.000
0.647
WP10-PWI-03
IPPLM
01. Jan 2010
0.15
3.236
0.647
0.000
0.000
0.647
WP10-PWI-05
IPPLM
01. Jan 2010
0.30
9.360
1.872
0.000
0.000
1.872
Total
0.60
15.833
3.167
0.000
0.000
3.167
WP10-PWI-02
IST
01. Jan 2010
0.20
5.000
1.000
0.000
0.000
1.000
WP10-PWI-05
IST
01. Jan 2010
0.40
40.000
8.000
10.000
4.000
12.000
Total
0.60
45.000
9.000
10.000
4.000
13.000
WP10-PWI-05
KIT
01. Jan 2010
0.50
52.500
10.500
0.000
0.000
10.500
Total
0.50
52.500
10.500
0.000
0.000
10.500
WP10-PWI-01
MEdC
01. Jan 2010
0.35
14.350
2.870
0.000
0.000
2.870
WP10-PWI-02
MEdC
01. Jan 2010
0.00
0.000
0.000
0.000
0.000
0.000
WP10-PWI-05
MEdC
01. Jan 2010
0.35
14.350
2.870
0.000
0.000
2.870
WP10-PWI-06
MEdC
01. Jan 2010
0.60
11.700
2.340
15.000
6.000
8.340
Total
1.30
40.400
8.080
15.000
6.000
14.080
WP10-PWI-01
MHST
01. Jan 2010
0.20
6.395
1.279
5.000
2.000
3.279
WP10-PWI-02
MHST
01. Jan 2010
0.10
3.954
0.791
0.000
0.000
0.791
Total
0.30
10.349
2.070
5.000
2.000
4.070
WP10-PWI-01
TEKES
01. Jan 2010
0.20
30.000
6.000
10.000
4.000
10.000
WP10-PWI-04
TEKES
01. Jan 2010
0.70
90.833
18.167
30.000
12.000
30.167
WP10-PWI-06
TEKES
01. Jan 2010
0.10
15.000
3.000
0.000
0.000
3.000
Total
1.00
135.833
27.167
40.000
16.000
43.167
WP10-PWI-05
University of Latvia
01. Jan 2010
1.00
16.627
3.325
20.000
8.000
11.325
Total
1.00
16.627
3.325
20.000
8.000
11.325
WP10-PWI-01
VR
01. Jan 2010
0.20
25.000
5.000
10.000
4.000
9.000
WP10-PWI-02
VR
01. Jan 2010
0.25
31.250
6.250
10.000
4.000
10.250
WP10-PWI-03
VR
01. Jan 2010
0.70
82.867
16.573
5.000
2.000
18.573
WP10-PWI-04
VR
01. Jan 2010
0.10
12.500
2.500
5.000
2.000
4.500
WP10-PWI-05
VR
01. Jan 2010
0.05
6.250
1.250
5.000
2.000
3.250
WP10-PWI-06
VR
01. Jan 2010
0.10
12.500
2.500
5.000
2.000
4.500
Total
1.40
170.367
34.073
40.000
16.000
50.073
WP10-PWI-04
ÖAW
01. Jan 2010
0.40
10.282
2.056
0.000
0.000
2.056
WP10-PWI-07
ÖAW
01. Jan 2010
0.30
9.756
1.951
0.000
0.000
1.951
Total
0.70
20.038
4.008
0.000
0.000
4.008
Grand total
25.20
2722.820
544.564
430.000
172.000
716.564
EFDA Workprogramme 2010
Plasma Wall Interaction
PWI 2010 TASK AGREEMENT
Chapter 1: Fuel retention as a function of wall materials foreseen for ITER
WP10-PWI-01
Between:The EFDA Leaderand the following Associates
- CEA
- MEdC
- FOM_Rijnhuizen
- MHST_Slovenia
- FZJ
- TEKES
- IPP
- VR
Index
1. Introduction
2. Objectives
3. Work Description and Breakdown
4. Scientific and Technical Reports
5. Priority Support Expenditure Forecast
6. Intellectual Property
7. Quality Assurance
8. Background Documentation
Annex 1: Summary financial table for Priority Support
Annex 2: Indicative mobility support
1. Introduction
From gas balance analysis, common features on the retention behaviour have been observed in different machines. It shows an initial high retention rate in a first phase of the discharge, decreasing towards a steady state value in a second phase. After the shot, the gas recovery corresponds to the gas trapped during the first phase, so that the associated retention mechanism seems to be transient (such as adsorption leading to weakly bound deuterium (D)). The long term recovery, overnight, over weekends and in maintenance periods, is more difficult to assess and makes extrapolation to ITER still difficult. However, from the DT campaign on JET (1997-1998) the amount of particles recovered in the period is not significant/dominant and represents about 10-15% of the total amount retained.
So far, most data on retention were obtained in all-carbon machines, so that comparison with carbon free machines (all-W ASDEX Upgrade, future ITER like Wall in JET) needs to be performed for a better prediction for ITER.
Retention from post-mortem PFC analysis suffers from averaging over many different plasma scenarios, often icluding wall conditioning such as He-GDC and boronisation, and disruptions. Moreover, the impact of long term outgasing between shots during the campaign (months) and air exposure of the samples when removed from the vessel is difficult to assess.
Scaling of retention rate as a function of plasma/ machine parameters is only poorly characterized (injection rate, incident flux/fluence, PFC materials, PFC temperature). However, the main retention mechanisms have been identified (co-deposition with C and/or Be, bulk diffusion and trapping in CFC and W) but their relative contributions in ITER conditions are still uncertain, and are a topic of active research, from laboratory experiments, modelling as well as integrated tokamak experiments.
2. Objectives
The aim of this Task Agreement is to improve our knowledge on fuel retention in wall materials foreseen for ITER using particle balance to evaluate “how many” particles are retained in the vessel and post mortem analysis to assess where these particles are retained. It is worth noting that these methods are complementary.
The scientific objectives of the task are to:
- perform an extensive post mortem analysis of PFCs for comparison with integrated particle balance results;
- assess sources of possible uncertainties on both methods (such as disruptions, outgassing, cleaning discharges for particle balance, non toroidal/poloidal uniformity, retention in gaps and hidden areas, bulk diffusion for post mortem analysis);
- establish and perform a complementary analysis programme to progress in identifying the retention mechanisms at stake;
- on a longer term : propose ITER relevant fuel retention diagnostics, from particle balance, in situ and/or post mortem analysis
3. Work Description and Breakdown
3.1 Structure
The Work Programme involves experiments on gas balance in several European fusion devices (ASDEX Upgrade, Tore Supra, TEXTOR and other possible relevant devices, JET for comparison) and subsequent surface analysis in different laboratories for comparison. It is coordinated by the SEWG on Gas Balance and Fuel Retention which:
- sets up the experimental work programme, including the request for machine time in the different fusion devices;
- follows the samples exchange for surface analysis;
- organizes SEWG meetings for collection of data, interpretation and extrapolation of results;
- summarizes the collected data in a final report.
Work under the present Task Agreement includes two subtasks:
WP10-PWI-01-01
Multi machine scaling of fuel retention for ITER (AUG, TS, TEXTOR (JET for comparison), other relevant devices, PSI devices)
· Complete studies of retention in C environment for different edge plasma regimes (TS, TEXTOR, and possibly other relevant devices)
· Study the retention in a full W environment for different regimes (L mode, type I ELM, type III ELMs and advanced tokamak regimes). Comparison with results in previous configurations as a function of carbon coverage (AUG)
· Study D retention in Be/W/mixed materials under high fluence (PISCES, IPP dual beam), see also SEWG on ITER material mix
· Assess the contribution of wall conditioning (boron) on the retention, in particular for full metallic devices
· From all the above experiments, establish a multi-machine scaling of retention and refine the fuel retention predictions for ITER
WP10-PWI-01-02
Characterisation of retention mechanisms using particle balance and post mortem analysis (AUG, TS, other relevant devices (JET for comparison), analysis in several associations)
· Perform an extensive post mortem analysis of PFCs for assessing where the fuel retained in the vessel is located: deposited layers, gaps, bulk material, flakes, remote areas, below limiter/divertor in order to improve mitigation measures (in plasma operation as well as for the design of PFCs) and fuel removal techniques
· Comparison with integrated particle balance results.
· Establish and perform complementary analysis program to progress in identifying the retention mechanisms at stake
3.2 Work Breakdown and involvement of Associations
The work breakdown and involvement of the Associates which results from the call from participation and the assessment conducted by the EFDA-CSU and the PWI-TF is given in Table 3.1
Table 3.1: Work Breakdown
Year
Work Description
Associate
Manpower Baseline Support (ppy)
Manpower Priority Support (ppy)
Hardware Priority Support (kEuros)
2010
WP10-PWI-01-01-03/CEA/BS
Scaling of fuel retention in Tore Supra
Extention of the database of retention rates as a function of Padd (ICRH vs LH) and Te (impurity seeding).
CEA
0.30
0.00
0.00
WP10-PWI-01-02-01/CEA/BS
Closing the D balance in Tore supra from particle balance and post mortem analysis (DITS project)
Comparison between D inventory from particle balance and post mortem analysis the frame of the DITS project
CEA
1.05
0.00
0.00
WP10-PWI-01-02-02/CEA/BS
Coordinated post mortem analysis of Tore Supra samples (DITS project)
· Perform the second analysis campaign of the Tore-Supra tiles (TDS, SIMS)
· Analyse D retention in gaps
· Characterize the structure of the deposited layers (thickness, morphology, atomic structure etc.) as a function of their location.
CEA
0.40
0.00
0.00
WP10-PWI-01-02-02/CEA/PS
Coordinated post mortem analysis of Tore Supra samples (DITS project)
· Perform the second analysis campaign of the Tore-Supra tiles (TDS, SIMS)
· Analyse D retention in gaps
· Characterize the structure of the deposited layers (thickness, morphology, atomic structure etc.) as a function of their location.
CEA
0.00
0.60
0.00
WP10-PWI-01-01-01/FOMRIJN/BS
H-retention in W and mixed systems
· Investigations of H-retention in W exposed to high fluxes in Pilot and the effect of irradiation damage: Influence of dpa-level, dpa-profile and surface temperature on H-retention during plasma exposure
· Investigations of H-retention in mixed W/C systems on Pilot/Magnum
· Investigations of H-retention in W during transient, ELM-like heat and particle fluxes on Pilot.
FOM_Rijnhuizen
0.90
0.00
0.00
WP10-PWI-01-01-02/FOMRIJN/PS
H-retention in W and mixed systems
· Investigations of H-retention in W exposed to high fluxes in Pilot and the effect of irradiation damage: Influence of dpa-level, dpa-profile and surface temperature on H-retention during plasma exposure
· Perform coordinated experiments (PISCES, TEXTOR and Pilot/Magnum) to investigate H-retention in mixed W/C systems
· Investigations of H-retention in W during transient, ELM-like heat and particle fluxes on Pilot -comparison to experiments in DIII-D/DiMES
FOM_Rijnhuizen
0.00
0.40
0.00
WP10-PWI-01-01-01/FZJ/BS
Joint TEXTOR, MAGNUM and PISCES experiments to investigate the fuel retention in tungsten and in the mixed tungsten-carbon system
FZJ
1.30
0.00
0.00
WP10-PWI-01-01-02/FZJ/PS
Joint TEXTOR, MAGNUM and PISCES experiments to investigate the fuel retention in tungsten and in the mixed tungsten-carbon system
FZJ
0.00
0.30
0.00
WP10-PWI-01-01-03/FZJ/BS
Fuel retention for ITER
Predictions of fuel retention in fusion machines taking into ac count tungsten as divertor material. and updated data for tritium retention (e.g. surface temperature dependence, mixing effects).
FZJ
0.20
0.00
0.00
WP10-PWI-01-01-04/FZJ/PS
Fuel retention for ITER
Predictions of fuel retention in fusion machines taking into ac count tungsten as divertor material. and updated data for tritium retention (e.g. surface temperature dependence, mixing effects).
FZJ
0.00
0.10
0.00
WP10-PWI-01-02-01/FZJ/PS
Investigations of fuel accumulation and material transport into gaps of ITER-like castellated structures
Perform series of experiments on TEXTOR (and DIII-D) to study carbon transport and fuel accumulation in the gaps of castellation structures taking into account:
-cell shape and orientation
-inclination of the magnetic field.
FZJ
0.00
0.20
5.00
WP10-PWI-01-02-02/FZJ/BS
Investigations of fuel accumulation and material transport into gaps of ITER-like castellated structures
Perform series of experiments on TEXTOR (and DIII-D) to study carbon transport and fuel accumulation in the gaps of castellation structures taking into account:
-cell shape and orientation
-inclination of the magnetic field.
FZJ
0.80
0.00
0.00
WP10-PWI-01-00/IPP/PS
Leadership SEWG Gas Balance and Fuel Retention
Task coordinator of task agreement:
Fuel retention as a function of wall materials foreseen for ITER
IPP
0.00
0.25
0.00
WP10-PWI-01-01-01/IPP/BS
Multi machine scaling of fuel retention for ITER
· Validation of the assessment procedure for inventories from the underlying retention processes for different tokamaks, such as ASDEX Upgrade, Tore Supra and JET.
· Extention of the multi machine scaling of fuel retention to ITER (AUG, TS, TEXTOR (JET for comparison), other relevant devices, PSI devices).
IPP
0.10
0.00
0.00
WP10-PWI-01-01-01/IPP/PS
Multi machine scaling of fuel retention for ITER
· Validation of the assessment procedure for inventories from the underlying retention processes for different tokamaks, such as ASDEX Upgrade, Tore Supra and JET.
· Extention of the multi machine scaling of fuel retention to ITER (AUG, TS, TEXTOR (JET for comparison), other relevant devices, PSI devices).
IPP
0.00
0.10
0.00
WP10-PWI-01-01-02/IPP/BS
Contribution of wall conditioning (boron) on the retention in the full-W device - ASDEX Upgrade:
-quantification of the existing boron data
- correlation of boron with D retention
IPP
0.50
0.00
0.00
WP10-PWI-01-01-03/IPP/BS
Retention in a full W environment for different regimes
· Studies of fuel (D) retention in the full W wall environment of ASDEX Upgrade for well defined discharge conditions at the outer divertor target plate.
· Exposure of bulk tungsten samples to series of identical discharges.
· Post mortem analysis (D retention) of tungsten samples (TDS, NRA)
· Comparison of the results with corresponding experiments in linear plasma devices (Pilot-PSI, Magnum-PSI, PISCES) and of other tokamak devices (TEXTOR, MAST)
IPP
0.50
0.00
0.00
WP10-PWI-01-01-04/IPP/PS
D Retention in Be/C/W/mixed materials
· Preparation of sample systems with mixed material layers on top of each of the different ITER PFM elements
· Exposure of samples to a range of D fluences at different incidence energies (IPP high current source and PISCES respectively).
· Post mortem studies of D-retention by ion-beam analysis and TDS.
· Studies of the influence of the structural properties of the mixed layers on retention.
· Investigations of the influence of impurities on D retention in ITER PFM elements (dual beam experiments)
IPP
0.00
0.25
0.00
WP10-PWI-01-01-05/IPP/BS
D Retention in Be/C/W/mixed materials
· Preparation of sample systems with mixed material layers on top of each of the different ITER PFM elements
· Exposure of samples to a range of D fluences at different incidence energies (IPP high current source and PISCES respectively).
· Post mortem studies of D-retention by ion-beam analysis and TDS.
· Studies of the influence of the structural properties of the mixed layers on retention.
· Investigations of the influence of impurities on D retention in ITER PFM elements (dual beam experiments)
IPP
0.50
0.00
0.00
WP10-PWI-01-01-06/IPP/BS
Gas balance measurements in AUG
· Investigations of fuel retention in the full tungsten divertor tokamak AUG using gas balance technique.
· Clarification of the effect of boron layer on the retention in a full metallic device
· Investigations of retention in different plasma regimes.
IPP
0.20
0.00
0.00
WP10-PWI-01-01-07/IPP/BS
Gas balance measurements in AUG.
· Improvement of the accuracy of gas balance measurements:
· Installation of the external volume and development of a new software for the data analysis to enable the determination of wall release
· Investigations of retention for different plasma regimes and wall coatings
IPP
0.20
0.00
0.00
WP10-PWI-01-01-08/IPP/PS
Fuel retention in W as function of dpa level of radiation damage
· Irradiation of ITER grade W samples with up to 5 MeV W+ ions to different levels of dpa
· Investigations of H-retention in W exposed to high fluxes and fluences in PILOT (FOM, Netherlands) and the effect of irradiation damage: Influence of dpa-level, dpa-profile and surface temperature on H-retention
· NRA analysis of exposed PILOT samples for hydrogen profile at front and back surface
IPP
0.00
0.20
0.00
WP10-PWI-01-02-01/IPP/BS
Post-mortem analysis of PFCs at ASDEX Upgrade for fuel retention studies
IPP
0.30
0.00
0.00
WP10-PWI-01-01-01/MEdC/BS
Providing W coated CFC samples for fuel retention measurements
MEdC
0.30
0.00
0.00
WP10-PWI-01-02-01/MEdC/BS
X-ray micro-tomography studies CFC samples for porosity network characterization
· Participation at DITS project - post mortem analysis by providing high resolution tomography measurements on CFC samples
· Qualification of the initial porosity of the new CFC ITER reference material NB41
· Porosity characterization of tungsten coated CFC samples
MEdC
0.65
0.00
0.00
WP10-PWI-01-02-02/MEdC/PS
X-ray micro-tomography studies CFC samples for porosity network characterization
· Participation at DITS project - post mortem analysis by providing high resolution tomography measurements on CFC samples
· Qualification of the initial porosity of the new CFC ITER reference material NB41
· Porosity characterization of tungsten coated CFC samples
MEdC
0.00
0.35
0.00
WP10-PWI-01-02-01/MHST/PS
Studies of fuel retention processes by detection of deuterium with micro-NRA (TEXTOR tiles and DITS project)
MHST_Slovenia
0.00
0.20
5.00
WP10-PWI-01-02-04/MHST/BS
Deuterium retention and release from Be and W surfaces - correlation of deuterium kinetics /absorption/desorption/ parameters with actual surface composition.
MHST_Slovenia
1.00
0.00
0.00
WP10-PWI-01-02-01/TEKES/BS
Characterisation of retention mechanisms in AUG
· Drilling samples from AUG tiles
· Post mortem surface analysis of the samples using SIMS and NRA and determining the retention of D in them
· Comparison of the obtained data with particle-balance measurements
TEKES
0.20
0.00
0.00
WP10-PWI-01-02-02/TEKES/PS
Characterisation of retention mechanisms in AUG
· Drilling samples from AUG tiles
· Post mortem surface analysis of the samples using SIMS and NRA and determining the retention of D in them
· Comparison of the obtained data with particle-balance measurements
· Production of new marker tiles for retention studies in AUG.
TEKES
0.00
0.20
10.00
WP10-PWI-01-02-01/VR/BS
· Characterisation of retention mechanisms using particle balance and post mortem analysis.
· Post mortem analysis of components of TEXTOR and Tore Supra : Composition of deposits and fuel retention in deposits
· Assessment of sources influencing observed discrepancies between post mortem and gas balance measurements
VR
0.05
0.00
0.00
WP10-PWI-01-02-01/VR/PS
· Characterisation of retention mechanisms using particle balance and post mortem analysis.
· Post mortem analysis of components of TEXTOR and Tore Supra : Composition of deposits and fuel retention in deposits
· Assessment of sources influencing observed discrepancies between post mortem and gas balance measurements
VR
0.00
0.20
10.00
WP10-PWI-01-02-02/VR/BS
· Characterisation of retention mechanisms using particle balance and post mortem analysis
· Assessment of long-term retention in PFC from TEXTOR and Tore Supra
· Calculation of fuel content in tiles from various locations in tokamaks.
VR
0.40
0.00
0.00
Total
9.85
3.35
30.00
3.3 JET related activities
No JET related activities are meant to be implemented under this Task Agreement. JET related activities are implemented under EFDA Art.6. However some JET activities can be mentioned for information in this TA when they closely related to the activity implemented under Art.5. JET data collected under the JET part of the EFDA WP can be brought together with other data under this TA when relevant for the progress of the work or used in multi- machine modelling activities under Art.5.
JET TF E and
TF FT
· Complete the fuel retention database (in D2, H2 and He) for comparison between the present carbon configuration and the future ITER like wall (TFE).
· Complete the post mortem analysis of JET PFCs, including gaps, Be PFCs etc (TF-FT), assess where the fuel is retained
· Perform fuel retention studies in the ILW configuration
3.4 Publications
· EFDA 2010 Work Programme / EU PWI TF
· 2007, 2008and 2009 reports of SEWG on Gas balance
4. Scientific and Technical Reports
4.1 Progress Reports
At the end of each calendar year, during the PWI TF annual meeting, the SEWG leader in charge of the task coordination shall present a report on all activities (under baseline and priority support) under the Task Agreement to the EFDA Leader for his approval. These reports shall integrate the progress made by each Association on each activity, and they shall indicate the level of achievement of the objectives, the situation of the activities, the allocation of resources and recommendations for the next year when applicable.
The EURATOM financial contribution will be made through the usual procedures for baseline support through the Contract of Association.
4.2 Report of achievements under Priority Support (final report and, when appropriate, intermediate reports)
In addition, achievement of Priority Support deliverables will be reported separately to the EFDA Leader. A final report shall be prepared by the SEWG leader in charge of the task coordination and submitted to the EFDA Leader. Each participating Association will have to report in one subsection on the degree to which the deliverables of their Tasks have been achieved and shall include a breakdown of expenditure. The Task Coordinator will collect the individual subsections into the final report for Priority Support activities addressing the associated milestones defined.
The EURATOM financial contribution will be made after approval of these reports by the EFDA Leader.
Table 4.1: Task Deliverables
Activity
Association
Priority Support Deliverables
Due Date
WP10-PWI-01-00/IPP/PS
IPP
Scientific report summarizing work within Task Agreement
31. Dec 2010
WP10-PWI-01-01-01/IPP/PS
IPP
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-01-02/FOMRIJN/PS
FOM_Rijnhuizen
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-01-02/FZJ/PS
FZJ
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-01-03/IPP/PS
IPP
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-01-04/FZJ/PS
FZJ
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-01-04/IPP/PS
IPP
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-01-06/IPP/PS
IPP
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-01-08/IPP/PS
IPP
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-02-01/FZJ/PS
FZJ
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-02-01/MHST/PS
MHST_Slovenia
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-02-01/VR/PS
VR
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-02-02/CEA/PS
CEA
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-02-02/MEdC/PS
MEdC
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-01-02-02/TEKES/PS
TEKES
Scientific reports on performed tasks
31. Dec 2010
4.3 Milestones
Mid 2010
SEWG Meeting: Collection and discussion of results obtained from the evaluation of experiments in 2009 and early 2010
October 2010:
Annual meeting of the EU TF on PWI: coordinated presentation of the results from the experimental campaigns in 2010
December 2010: Final report sent to EFDA-CSU.
5. Priority Support Expenditure Forecast
The forecast of the total expenditures eligible for priority support in this Task Agreement is 415.832 kEuro. A full breakdown of forecast of expenditures is given in Annex 1. The Community financial contribution will be up to a maximum of 89.166 kEuro under Art. 8.2a and 8.2b of the Contract of Association.
For exchange of scientists between the involved Associations details of the forecast of expenditure under the Mobility Agreement is shown in Annex 2. This data shall be included in the annual Mobility Plan of the Associations .
6. Intellectual Property
The Associates shall identify, in the Task Agreement reports, all information relevant from the Intellectual Property Rights point of view. Guidelines regarding the content of this IPR chapter are given in the EFDA Explanatory Note to the Associates of 28 November 2007 (IPR report (art.5) final).
7. Quality Assurance
EFDA QA rules applicable where appropriate (EFDA-Annex QA- EFDA QA requirements for Suppliers (EFDA_D_2AN6G6)).
8. Background Documentation
· EFDA 2010 Work Programme / EU PWI TF
· 2007, 2008and 2009 reports of SEWG on Gas balance
Annex 1: Summary financial table for Priority Support
Year
Association
Activity
Manpower
Hardware expenditure
Consumables expenditure
Other expenditures
Total
Comments
ppy
k€
k€
k€
k€
k€
2010
CEA
WP10-PWI-01-02-02/CEA/PS
0.60
98.40
0.00
0.00
0.00
98.40
FOM_Rijnhuizen
WP10-PWI-01-01-02/FOMRIJN/PS
0.40
59.60
0.00
0.00
0.00
59.60
FZJ
WP10-PWI-01-01-02/FZJ/PS
0.30
29.74
0.00
0.00
0.00
29.74
FZJ
WP10-PWI-01-01-04/FZJ/PS
0.10
13.52
0.00
0.00
0.00
13.52
FZJ
WP10-PWI-01-02-01/FZJ/PS
0.20
19.83
5.00
0.00
0.00
24.83
IPP
WP10-PWI-01-00/IPP/PS
0.25
30.00
0.00
0.00
0.00
30.00
To be accepted by EFDA SC
IPP
WP10-PWI-01-01-01/IPP/PS
0.10
12.00
0.00
0.00
0.00
12.00
IPP
WP10-PWI-01-01-04/IPP/PS
0.25
23.00
0.00
0.00
0.00
23.00
IPP
WP10-PWI-01-01-08/IPP/PS
0.20
24.00
0.00
0.00
0.00
24.00
MEdC
WP10-PWI-01-02-02/MEdC/PS
0.35
14.35
0.00
0.00
0.00
14.35
MHST_Slovenia
WP10-PWI-01-02-01/MHST/PS
0.20
6.40
5.00
0.00
0.00
11.40
TEKES
WP10-PWI-01-02-02/TEKES/PS
0.20
30.00
10.00
0.00
0.00
40.00
VR
WP10-PWI-01-02-01/VR/PS
0.20
25.00
10.00
0.00
0.00
35.00
Total 2010
3.35
385.83
30.00
0.00
0.00
415.83
Annex 2: Indicative mobility Support
Year
Association
Estimated number of trips
Estimated total cost (k€)
Comments
2010
CEA
8
8
Coordinated sample analysis in IPP, FZJ, VTT, ENEA.
FOM_Rijnhuizen
5
8
Irradiation and analysis at IPP-Garching, Coordinated experiments at UCSD PISCES, ITPA mission
FZJ
2
6
ITPA DSOL, DIII-D-Experiment
IPP
7
9
SEWG Fuel Retention, General EU PWI TF meeting
MEdC
3
3
TF meeting, SEWG Annual Meeting, CEA Cadarache
MHST_Slovenia
4
7
FZ Juelich, SEWG meeting, MPI, Garching
TEKES
2
10
Ion-beam analyses at IPP, Garching
VR
9
14
FZJ: Experiments, collection of samples, etc.; ITPA, SEWG meeting
CEA: DITS project
Total
40
65
EFDA Workprogramme 2010
Plasma Wall InteractionPWI 2010 TASK AGREEMENT
Chapter 2: Exploration of fuel removal methods compatible with retention in mixed materials and metals, including beryllium
WP10-PWI-02
Between:The EFDA Leaderand the following Associates
- Belgium_ERM-KMS
- ENEA_CNR
- MEdC
- Belgium_SCK-CEN
- FZJ
- MHST_Slovenia
- CCFE
- IPP
- VR
- CEA
- IPPLM_Poland
- CIEMAT
- IST
Index
1. Introduction
2. Objectives
3. Work Description and Breakdown
4. Scientific and Technical Reports
5. Priority Support Expenditure Forecast
6. Intellectual Property
7. Quality Assurance
8. Background Documentation
Annex 1: Summary financial table for Priority Support
Annex 2: Indicative mobility support
1. Introduction
The retention rate of tritium in the ITER vessel is likely to require in-situ tritium recovery during operations or during the maintenance period (depending on the choice of first wall and divertor materials), or methods to actively control the inventory by limiting the tritium uptake during each pulse. In addition to scenario improvements allowing a reduction of tritium retention, detritiation techniques shall be made available to insure a safe operation of ITER. Two main types of actions are foreseen:
- heating the PFCs in order to release the tritium;
- removing the material in which the tritium is trapped (mainly in the co-deposition).
Among methods used for heating one should make the difference between techniques based on PFC bulk heating and those relying on surface heating.
Bulk heating in vacuum (to around 350C) is a practical technique for dealing with tritium trapped in beryllium co-deposits, and heating of the divertor alone might address much of this retention.For tritiated hydrocarbon deposits, however, the required temperature for efficient detritiation is impractically high. In order to enhance the efficiency to a sufficient level it is needed to operate under oxidising atmosphere (O2 or steam). Unfortunately, oxidation can induce de-conditioning of the PFCs, requiring extensive re-conditioning, and could therefore be a very time consuming method. It is also foreseen that the choice of this technique would require significant changes in terms of design for the PFCs and for the tritium plant in order to handle the exhaust gases produced. This technique has been extensively studied, however, and has proven its efficiency as far as detritiation is concerned and should not be therefore ruled out.
The removal of material (co-deposits) can also be performed by photonic methods. The main advantage is that, as well as detritiating, these techniques also contribute to reducing the dust inventory (co-deposition being one of the sources for dust production). Furthermore they are capable of removing co-deposits without harming the PFC surface, and could also be used for window and mirror cleaning (which may be necessary for several of the optical diagnostics). With these removal methods, it would be necessary to collect aerosols and dusts produced by the co-deposit ablation. Therefore, it is requested to proceed with a feasibility study on a potential remote handled application of a photonic ablation technique on ITER, emphasising the need to guarantee an efficient collection of the wastes.
Besides this ITER will certainly have issues with tritium retention in mixed materials involving Be and W in conjunction with carbon and oxygen impurities. For all technologies, Tasks are expected to include quantification of the removal rates, and applicability to ITER in their objectives.
2. Objectives
The aim of this Task Agreement is to:
· Develop an integrated scenario for fuel removal in ITER:
- Explore possible methods to limit tritium uptake during the discharge
- Derive a credible tritium inventory control scheme relying on developed cleaning techniques to meet ITER operational requirements.
- Assess combined efficiency, removal rates and schedule needed.
· Assess efficiency of developed fuel removal methods (heating, chemical and photonic) for reducing hydrogenic retention in co-deposits as well as in metals and mixed materials
· Explore new fuel removal methods, targeted at hydrogenic retention in metals (for ITER with future all-metal divertor)
· Investigate wall conditioning scenarios (in particular RF conditioning, in collaboration with the EFDA TG on heating and current drive).
3. Work Description and Breakdown
3.1 Structure
The Work Programme involves laboratory-based experiments in dedicated facilities; experiments on fuel recovery in several European fusion devices (JET, ASDEX Upgrade, Tore Supra, TEXTOR and others); and surface analysis of treated samples in different laboratories for comparison. It is coordinated by the SEWG on Fuel Recovery which:
- identifies necessary experiments or analysis;
- supports requests for machine time in the different fusion and laboratory devices;
- facilitates exchange of treated samples for surface analysis at different laboratories;
- organizes SEWG meetings for collection of data, interpretation and extrapolation of results;
- summarises the collected data in a final report.
Work under the present Task Agreement includes four activities:
WP10-PWI-02-01
Wall conditioning
Investigate wall conditioning techniques (particularly RF conditioning) in tokamaks, with emphasis on fuel removal efficiency, operation under ITER conditions, and side effects such as dust production and plasma restart.
WP10-PWI-02-02
Plasma assisted chemical cleaning methods
· Explore the impact of repetitive oxidising plasmas (GDC/RF) on beryllium bulk properties and other in-vessel components.
· Study the effect of sample temperature for oxidative or advanced chemical cleaning (with or without glow discharge) on oxide film formation, and demonstrate beryllium oxide removal rates
· Resolve the impact of nitrogen-containing molecules on cleaning processes and understand the discrepancy between laboratory and tokamak experience
WP10-PWI-02-03
Phototonic cleaning methods
· Improve the understanding of the break-up processes for metallic films in photonic "cleaning", such as measuring the hydrogenic content of the particulates relative to the film composition, optimising gaseous release, and preventing spread of dust. Assess practical methods of exploiting laser techniques in ITER.
WP10-PWI-02-04
Fuel removal in gaps
· Develop methods for the removal of deposited films in tile gaps and castellations, measuring the efficiency as function of aspect ratio, etc. Possible techniques are glow discharge cleaning in oxygen or O-based gas mixtures (for which the relative importance of the ion species should be quantified), and use of a plasma torch
3.2 Work Breakdown and involvement of Associations
The work breakdown and involvement of the Associates which results from the call from participation and the assessment conducted by the EFDA-CSU and the PWI-TF is given in Table 3.1
Table 3.1: Work Breakdown
Year
Work Description
Associate
Manpower Baseline Support (ppy)
Manpower Priority Support (ppy)
Hardware Priority Support (kEuros)
2010
WP10-PWI-02-01-01/ERMKMS/BS
Joint Ion Cyclotron Wall Conditioning experiments in TEXTOR, ASDEX-Upgrade, Tore Supra (and JET) and coordinated post mortem sample analysis
Belgium_ERM-KMS
0.85
0.00
0.00
WP10-PWI-02-01-02/ERMKMS/PS
Joint Ion Cyclotron Wall Conditioning experiments in TEXTOR, ASDEX-Upgrade, Tore Supra (and JET) and coordinated post mortem sample analysis
Belgium_ERM-KMS
0.00
0.40
10.00
WP10-PWI-02-02-01/SCKCEN/BS
Establishing an experimental set-up to investigate the effect of advanced oxidative cleaning on oxide film formation.
· Completion of the Beryllium glovebox in SCK•CEN's tritium laboratory.
· Creation of the correct experimental conditions for decarbonizing the tiles using either ozone or atomic oxygen.
· Preparation of Beryllium samples for the experiments.
· Experiments with the ozone treatment of carbon coated beryllium samples and associated laboratory analyses
Belgium_SCK-CEN
1.20
0.00
0.00
WP10-PWI-02-01-01/CEA/BS
Development of ion cyclotron wall conditioning in Tore Supra:
· the multi machine analysis of data collected in 2008
· the definition and planning of further experiments in TS, TEXTOR, and AUG
· the characterisation and development of numerical models of ICRF wall conditioning discharges
CEA
0.90
0.00
0.00
WP10-PWI-02-01-02/CEA/PS
Coordinated development of ion cyclotron wall conditioning
· the multi machine analysis of data collected in 2008
· the definition and planning of further experiments in TS, TEXTOR, and AUG
· the characterisation and development of numerical models of ICRF wall conditioning discharges
CEA
0.00
0.60
0.00
WP10-PWI-02-02-01/CEA/BS
Feasibility study of multi-point plasma plasma discharge for fuel removal (methods developed for unburnt hydrocarbon soots deposits), including gaps
CEA
0.40
0.00
0.00
WP10-PWI-02-02-02/CEA/BS
Investigations of the impact of dissociative recombination, collisions and nitrogen containing molecules on chemical cleaning processes
CEA
0.50
0.00
0.00
WP10-PWI-02-03-01/CEA/BS
Optimisation of laser cleaning on Tore supra samples, including gaps
CEA
0.75
0.00
0.00
WP10-PWI-02-04-01/CEA/BS
Evaluation of microdischarge methods for the cleaning of tile gaps and castellations
· Construction of micro-discharge plasma sources in oxygen containing mixtures, preparation of hydrogenated amorphous carbon coatings on metal surfaces, and preliminary measurements
· Determination of erosion rate and its dependence on plasma parameters (gas mixture, pressure and current) and on the aspect ratio
CEA
0.50
0.00
0.00
WP10-PWI-02-02-01/CIEMAT/BS
Optimization of carbon film removal by ammonia plasmas
CIEMAT
0.10
0.00
0.00
WP10-PWI-02-02-01/CIEMAT/PS
Optimization of carbon film removal by ammonia plasmas
CIEMAT
0.00
0.30
0.00
WP10-PWI-02-02-02/CIEMAT/BS
Nitrogen plasma assisted chemical cleanining methods
CIEMAT
1.00
0.00
0.00
WP10-PWI-02-03-01/CIEMAT/BS
Impact of surrounding atmosphere on Laser cleaning methods.
CIEMAT
0.50
0.00
0.00
WP10-PWI-02-02-01/ENEACNR/BS
Study of scavenging effect to reduce the redeposition of hydrogenated films containing carbon and tungsten.
ENEA_CNR
0.66
0.00
0.00
WP10-PWI-02-01-01/FZJ/PS
Joint ICWC experiments in TEXTOR, ASDEX-Upgrade, Tore Supra (and JET) and coordinated post mortem sample analysis
FZJ
0.00
0.20
0.00
WP10-PWI-02-01-02/FZJ/BS
Joint ICWC experiments in TEXTOR, ASDEX-Upgrade, Tore Supra (and JET) and coordinated post mortem sample analysis
FZJ
0.50
0.00
0.00
WP10-PWI-02-02-01/FZJ/BS
Joint exploration of new wall cleaning methods using GDC in Oxygen, NH3 and N2O
FZJ
0.90
0.00
0.00
WP10-PWI-02-02-01/FZJ/PS
Joint exploration of new wall cleaning methods using GDC in Oxygen, NH3 and N2O.
FZJ
0.00
0.10
0.00
WP10-PWI-02-04-01/FZJ/BS
Gap cleaning using H2, O2 using GDC and ECR plasma discharges
FZJ
0.30
0.00
0.00
WP10-PWI-02-01-01/IPP/BS
RF wall conditioning techniques in ASDEX Upgrade
· Execution of experiments using different poloidal field in order to optimise the ICRF discharge volume
· Application of tracer gases to quantify the efficiency of wall cleaning
· Comparison of the results with extended glow discharge
IPP
0.40
0.00
0.00
WP10-PWI-02-01-02/IPP/PS
RF wall conditioning techniques in ASDEX Upgrade
· Execution of experiments using different poloidal field in order to optimise the ICRF discharge volume
· Application of tracer gases to quantify the efficiency of wall cleaning
· Comparison of the results with extended glow discharge
IPP
0.00
0.20
0.00
WP10-PWI-02-02-01/IPP/BS
Erosion and deposition chemistry in nitrogen containing discharges
· Measurements of erosion rate with/without ion bombardment for mixtures of H2/N2 and H2/NH3 for identical total N/H ratios in the gas phase (different N/H ratios, different ion energies and possibly different temperatures). Clarification of the role of chemical sputtering.
· Measurements of deposition in CH4/H2/N2 and CH4/H2/NH3 with and without ion bombardment (as function of ion energy, N/C/H ratio, and possibly temperature) Clarification of the role of the role of gas phase reactions.
· Execution of tile gap deposition (and erosion) experiments for selected parameters
IPP
0.50
0.00
0.00
WP10-PWI-02-04-01/IPP/BS
Fuel removal in tile gaps and castellations by oxygen plasmas
· Quantification of oxygen ion flux (mass and energy distribution using RFA and Plasma Monitor) for different plasma conditions.
· Quantification of oxygen and noble gas ion flux in X/O2 mixtures (X = Ar, He, ..) for different mixing ratios and plasma conditions.
· Measurements of erosion rate with ion bombardment for quantified gas mixtures as a function of temperature and ion energy
· Comparison of erosion measurements with and without ion bombardment for different gas mixtures. Clarification of the role of ions and neutral reactive oxygen species for erosion
· Execution of tile gap experiments for selected conditions (detailed determination of erosion profiles at the bottom of the gap and comparison to simulations)
IPP
0.30
0.00
0.00
WP10-PWI-02-04-02/IPP/BS
Modelling of fuel removal in gaps
IPP
0.20
0.00
0.00
WP10-PWI-02-03-01/IPPLM/BS
Removal efficiency of laser cleaning techniques
· Execution of removal experiments on AUG samples PVDed and Plasma Sprayed with Tungsten and on calibrated samples provided by FZJ
· Comparison of removal efficiency and rates for different surroundings (vacuum, O2, N2) and laser parameters
· Development of LIBS method in a view of its suitability for a diagnostic method for tritium inventory control in next step devices.
IPPLM_Poland
0.57
0.00
0.00
WP10-PWI-02-03-02/IPPLM/PS.
Removal efficiency of laser cleaning techniques
· Execution of removal experiments on AUG samples PVDed and Plasma Sprayed with Tungsten and on calibrated samples provided by FZJ
· Comparison of removal efficiency and rates for different surroundings (vacuum, O2, N2) and laser parameters
· Development of LIBS method in a view of its suitability for a diagnostic method for tritium inventory control in next step devices.
IPPLM_Poland
0.00
0.15
0.00
WP10-PWI-02-01-01/IST/PS
Wall Conditioning
· Analysis of the existing data on ICWC experiments in AUG, TS, TEXTOR in order to establish trends in plasma production process and evolution of plasma parameters
· Analysis of the existing data on wall conditioning efficiency and comparison with the data obtained in recent JET experiments.
· Preparation and accomplishment of new series of experiments in tokamaks to optimize the ICRF plasma for wall conditioning.
· Adapting of the ICWC method for further use in experiments with W-wall
IST
0.00
0.20
0.00
WP10-PWI-02-01-02/IST/BS
Wall Conditioning
· Analysis of the existing data on ICWC experiments in AUG, TS, TEXTOR in order to establish trends in plasma production process and evolution of plasma parameters
· Analysis of the existing data on wall conditioning efficiency and comparison with the data obtained in recent JET experiments.
· Preparation and accomplishment of new series of experiments in tokamaks to optimize the ICRF plasma for wall conditioning.
· Adapting of the ICWC method for further use in experiments with W-wall
IST
0.20
0.00
0.00
WP10-PWI-02-04-01/MEdC/BS
Removal of codeposited material from gaps with a plasma torch
· Manufacturing of new constructive elements of the plasma torch suitable to work in reactive gases
· Studies of stability of source operation in air and other reactive gases
· Experiments of inside gap cleaning of carbon and mixed layers with plasma nitrogen/argon/reactive gases plasma torch
· Assessment of cleaning on the bottom of narrow gaps
· Examination of aspects regarding source integration with a robotic arm.
MEdC
1.20
0.00
0.00
WP10-PWI-02-04-02/MEdC/BS
Laboratory models for the co-deposited layers
· Realization and characterization of model co-deposited layers and their use in conjunction with fuel removal techniques
· Studies of the deposition and chemical transformation of Al/C + hydrogen layers, Be/C + hydrogen layers, or similar layers
MEdC
1.00
0.00
0.00
WP10-PWI-02-04-03/MEdC/BS
Production of controlled laboratory co-deposited layers for fuel removal studies
· Definition of parameters for which layers with pre-defined carbon/metal content are obtained; composition characterization.
· Submission of composite layers for validation of fuel removal procedures
· Identification of the agents of the fast chemical change in metal (aluminium)/carbon + hydrogen layers at contact with the ambient
MEdC
0.40
0.00
0.00
WP10-PWI-02-02-03/MHST/BS
· Study of influence of ammonia on a-C:H formation in support of nitrogen scavenger technique
· Comparison of different fuel removal techniques using low pressure DC, RF, and atmospheric pressure RF discharges.
MHST_Slovenia
0.80
0.00
0.00
WP10-PWI-02-02-04/MHST/BS
Detailed characterisation of reaction products from removal of a-C:H with mixed H2/N2 plasmas
MHST_Slovenia
0.30
0.00
0.00
WP10-PWI-02-02-04/MHST/PS
Detailed characterisation of reaction products from removal of a-C:H with mixed H2/N2 plasmas
Installation of differentially pumped mass spectrometer
MHST_Slovenia
0.00
0.10
0.00
WP10-PWI-02-04-03/MHST/BS
Removal of a-C:H and interaction of Plasma Facing Components with neutral oxygen atoms
· Application of neutral, free oxygen atoms for fuel removal in castellated structures similar to those foreseen in ITER
· Studies of formation of tungsten oxide on tungsten surfaces during treatment with oxygen atoms
· Demonstration the possibility that tungsten oxide layers can be easily removed by hydrogen plasma if appropriate parameters are applied
MHST_Slovenia
0.90
0.00
0.00
WP10-PWI-02-04-04/MHST/BS
Deposition of multi component C(W,Mg) thin films by sputtering for fuel removal studies
MHST_Slovenia
1.00
0.00
0.00
WP10-PWI-02-00/CCFE/PS
Leadership SEWG Fuel Removal
Task coordinator of task agreement:
Exploration of fuel removal methods compatible with retention in mixed materials and metals, including beryllium
CCFE
0.00
0.25
0.00
WP10-PWI-02-01-01/VR/BS
Effectiveness of fuel removal by wall conditioning methods : post mortem analysis of samples before/after treatment
VR
0.10
0.00
0.00
WP10-PWI-02-03-01/VR/PS
Effectiveness of photonic cleaning and dust generation associated with cleaning
VR
0.00
0.25
10.00
WP10-PWI-02-03-02/VR/BS
Surface structure of surfaces treated by various cleaning methods: photonic and wall conditioning
VR
0.50
0.00
0.00
Total
17.43
2.75
20.00
3.3 JET related activities
No JET related activities are meant to be implemented under this Task Agreement. JET related activities are implemented under EFDA Art.6. However some JET activities can be mentioned for information in this TA when they closely relate to the activity implemented under Art.5. JET data collected under the JET part of the EFDA WP can be brought together with other data under this TA when relevant for the progress of the work or used in multi- machine modelling activities under Art.5.
JET TF FT
· Test fuel removal techniques on JET PFCs, in particular containing Be (TF FT)
· Assess the efficiency of ICRF wall conditioning in the carbon configuration of JET, to be compared with the ILW configuration.
3.4 Publications
· EFDA 2010 Work Programme / EU PWI TF
· 2008 and 2009report of SEWG on Fuel Removal
4. Scientific and Technical Reports
4.1 Progress Reports
At the end of each calendar year, during the PWI TF annual meeting, the SEWG leader in charge of the task coordination shall present a report on all activities (under baseline and priority support) under the Task Agreement to the EFDA Leader for his approval. These reports shall integrate the progress made by each Association on each activity, and they shall indicate the level of achievement of the objectives, the situation of the activities, the allocation of resources and recommendations for the next year when applicable.
The EURATOM financial contribution will be made through the usual procedures for baseline support through the Contract of Association.
4.2 Report of achievements under Priority Support (final report and, when appropriate, intermediate reports)
In addition, achievement of Priority Support deliverables will be reported separately to the EFDA Leader. A final report shall be prepared by the SEWG leader in charge of the task coordination and submitted to the EFDA Leader. Each participating Association will have to report in one subsection on the degree to which the deliverables of their Tasks have been achieved and shall include a breakdown of expenditure. The Task Coordinator will collect the individual subsections into the final report for Priority Support activities addressing the associated milestones defined.
The EURATOM financial contribution will be made after approval of these reports by the EFDA Leader.
Table 4.1: Task Deliverables
Activity
Association
Priority Support Deliverables
Due Date
WP10-PWI-02-00/CCFE/PS
CCFE
Scientific report summarizing work within Task Agreement
31. Dec 2010
WP10-PWI-02-01-01/FZJ/PS
FZJ
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-01-01/IST/PS
IST
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-01-01/VR/PS
VR
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-01-02/CEA/PS
CEA
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-01-02/ERMKMS/PS
Belgium_ERM-KMS
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-01-02/IPP/PS
IPP
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-02-01/CIEMAT/PS
CIEMAT
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-02-01/FZJ/PS
FZJ
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-02-02/SCKCEN/PS
Belgium_SCK-CEN
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-02-04/MHST/PS
MHST_Slovenia
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-03-01/VR/PS
VR
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-03-02/IPPLM/PS
IPPLM_Poland
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-02-04-03/MEdC/PS
MEdC
Scientific reports on performed tasks
31. Dec 2010
4.3 Milestones
Mid 2010
SEWG Meeting: Collection and discussion of results obtained from the evaluation of experiments in 2009 and early 2010
October 2010:
Annual meeting of the EU TF on PWI: coordinated presentation of the results from the experimental campaigns in 2010
December 2010: Final report sent to EFDA-CSU.
5. Priority Support Expenditure Forecast
The forecast of the total expenditures eligible for priority support in this Task Agreement is 296.968 kEuro. A full breakdown of forecast of expenditures is given in Annex 1. The Community financial contribution will be up to a maximum of 63.394 kEuro under Art. 8.2a and 8.2b of the Contract of Association.
For exchange of scientists between the involved Associations details of the forecast of expenditure under the Mobility Agreement is shown in Annex 2. This data shall be included in the annual Mobility Plan of the Associations .
6. Intellectual Property
The Associates shall identify, in the Task Agreement reports, all information relevant from the Intellectual Property Rights point of view. Guidelines regarding the content of this IPR chapter are given in the EFDA Explanatory Note to the Associates of 28 November 2007 (IPR report (art.5) final).
7. Quality Assurance
EFDA QA rules applicable where appropriate (EFDA-Annex QA- EFDA QA requirements for Suppliers (EFDA_D_2AN6G6)).
8. Background Documentation
· EFDA 2010 Work Programme / EU PWI TF
· 2008 and 2009 report of SEWG on Fuel Removal
Annex 1: Summary financial table for Priority Support
Year
Association
Activity
Manpower
Hardware expenditure
Consumables expenditure
Other expenditures
Total
Comments
ppy
k€
k€
k€
k€
k€
2010
Belgium_ERM-KMS
WP10-PWI-02-01-02/ERMKMS/PS
0.40
42.59
10.00
0.00
0.00
52.59
CEA
WP10-PWI-02-01-02/CEA/PS
0.60
63.00
0.00
0.00
0.00
63.00
CIEMAT
WP10-PWI-02-02-01/CIEMAT/PS
0.30
27.00
0.00
0.00
0.00
27.00
FZJ
WP10-PWI-02-01-01/FZJ/PS
0.20
27.04
0.00
0.00
0.00
27.04
FZJ
WP10-PWI-02-02-01/FZJ/PS
0.10
13.52
0.00
0.00
0.00
13.52
IPP
WP10-PWI-02-01-02/IPP/PS
0.20
24.00
0.00
0.00
0.00
24.00
IPPLM_Poland
WP10-PWI-02-03-02/IPPLM/PS
0.15
3.24
0.00
0.00
0.00
3.24
IST
WP10-PWI-02-01-01/IST/PS
0.20
5.00
0.00
0.00
0.00
5.00
MHST_Slovenia
WP10-PWI-02-02-04/MHST/PS
0.10
3.95
0.00
0.00
0.00
3.95
CCFE
WP10-PWI-02-00/CCFE/PS
0.25
36.38
0.00
0.00
0.00
36.38
VR
WP10-PWI-02-03-01/VR/PS
0.25
31.25
10.00
0.00
0.00
41.25
Total 2010
2.75
276.97
20.00
0.00
0.00
296.97
Annex 2: Indicative mobility Support
Year
Association
Estimated number of trips
Estimated total cost (k€)
Comments
2010
Belgium_ERM-KMS
10
2
visiting other machines and doing experiments
Belgium_SCK-CEN
2
4
TF meetings
CEA
10
10
Participation at RF wall conditioning experiments in TEXTOR, AUG
Attendance TF meetings
CIEMAT
6
11
Visits to the Josef Stefan Institute, Ljubljana
Visits to the National Institute for Laser, Plasma and Radiation Physics Atomistilor, Bucharest
Josef Stefan Institute
Visits to IPPLM Warsaw
ENEA_CNR
2
4
TF meetings
FZJ
2
4
TF meetings
IPP
2
2
SEWG Removal
IPPLM_Poland
3
12
TF meetings; Experiments in Madrid
IST
3
7
Participation in experiments on AUG, TEXTOR and TS
MEdC
4
4
SEWG annual meeting, CEA Cadarache,
Joint experiments at MHEST and CIEMAT
MHST_Slovenia
20
26
Joint experiments: Bucharest, Madrid, Toulouse, Juelich, Font Romeu
CCFE
2
4
TF meetings
VR
4
6
TF meetings
Total
68
92
EFDA Workprogramme 2010
Plasma Wall InteractionPWI 2010 TASK AGREEMENT
Chapter 3: Dust generation and characterization in different devices, including the impact of fuel removal methods on dust production
WP10-PWI-03
Between:The EFDA Leaderand the following Associates
- CEA
- FZJ
- ENEA_CNR
- IPP
- ENEA_Frascati
- IPPLM_Poland
- FOM_Rijnhuizen
- VR
Index
1. Introduction
2. Objectives
3. Work Description and Breakdown
4. Scientific and Technical Reports
5. Priority Support Expenditure Forecast
6. Intellectual Property
7. Quality Assurance
8. Background Documentation
Annex 1: Summary financial table for Priority Support
Annex 2: Indicative mobility support
1. Introduction
The formation and accumulation of carbon and metal dust in a fusion reactor may create, like T retention, serious safety and operational problems. A strategy to deal with the dust accumulation has been accepted into the ITER baseline.
Dust sampling and analysis have been performed in different facilities, showing discrepancies between devices. The most important issues to be addressed are the following:
· Mechanisms for dust generation during plasma/maintenance phase including conditioning and fuel removal techniques
· Quantification of dust production in tokamaks from all the processes above
· Physics basis for techniques for dust removal and dust diagnostics
2. Objectives
The aim of this Task Agreement is to improve our knowledge on dust generation and its characterization in different tokamaks. It also includes the development of dust generation and transport models in order to provide better predictions for ITER.
3. Work Description and Breakdown
3.1 Structure
The Work Programme involves the collection of dust in several European fusion devices (ASDEX Upgrade, Tore Supra, TEXTOR and others, JET for comparison) and subsequent analysis in different laboratories for comparison, as well as development of dust diagnostics. It is coordinated by the SEWG on Dust in Fusion Devices which:
- sets up the experimental work programme, including the specification for dust collection and characterisation in the different fusion devices;
- follows the samples exchange for laboratory analysis;
- organizes SEWG meetings for collection of data, interpretation and extrapolation of results;
- summarises the collected data in a final report.
Work under the present Task Agreement includes three activities:
WP10-PWI-03-01
Dust generation in present devices
· Metal dust formation (W and Be): Identification of dust generation mechanisms. Validate modelling for dust creation and suspension. Implications for ITER standard scenario.
· Characterize dust generation in present devices (TS, TEXTOR, AUG and possibly other relevant devices; comparison to JET)): location in vacuum vessel, generation rates, physical and chemical properties (size, reactivity, surface specific area, fuel content, etc)
WP10-PWI-03-02
Conversion of co-deposits to dust
· Assess the dust conversion factor (gross erosion to dust production) for different EU devices.
· Assessment of dust generation by various techniques for fuel and co-deposit removal (see also SEWG on fuel removal).
WP10-PWI-03-03
Dust and plasma operation
· Improve detection of dust in the plasma and relate the dust generation to discharge conditions.
· Improve understanding of the impact of dust formation on the plasma performance and operation.
3.2 Work Breakdown and involvement of Associations
The work breakdown and involvement of the Associates which results from the call from participation and the assessment conducted by the EFDA-CSU and the PWI-TF is given in Table 3.1
Table 3.1: Work Breakdown
Year
Work Description
Associate
Manpower Baseline Support (ppy)
Manpower Priority Support (ppy)
Hardware Priority Support (kEuros)
2010
WP10-PWI-03-01-01/CEA/BS
Computational investigation of dust formation by droplet formation of melting metals.
CEA
0.50
0.00
0.00
WP10-PWI-03-01-02/CEA/BS
Laser ablation for calibrated spectroscopy measurements of erosion and dust formation studies:
· Synthesis of the metallic particles formed during tokamak operation in the different devices and correlation with the conditions of operation.
· Influence of the laser irradiation (energy deposition, pulse duration) and ambient (nature and pressure of gas) conditions on the particle morphologies (W, Al)
· Comparison between laser-induced particles and dusts generated in tokamaks, and determination of mechanisms formation.
CEA
1.50
0.00
0.00
WP10-PWI-03-03-01/CEA/BS
Stereoscopic Imaging of dust and UFOs in ASDEX Upgrade
· Analysis of stereoscopic camera measurements performed on AUG:
· Attempts to relate dust generation and transport to discharge conditions. Comparison with theory and modelling.
· Participation in new fast camera measurements of dust and UFOs in AUG.
CEA
0.30
0.00
0.00
WP10-PWI-03-03-01/CEA/PS
Stereoscopic Imaging of dust and UFOs in ASDEX Upgrade
· Analysis of stereoscopic camera measurements performed on AUG:
· Attempts to relate dust generation and transport to discharge conditions. Comparison with theory and modelling.
· Participation in new fast camera measurements of dust and UFOs in AUG.
CEA
0.00
0.50
10.00
WP10-PWI-03-03-02/CEA/BS
Assessment of dust production in Tore Supra using an electrostatic detector
CEA
0.20
0.00
0.00
WP10-PWI-03-03-01/ENEACNR/BS
Detection of submicron metal dust particles by aerogel on FTU
· Perform test of silica aerogel as a target for collecting metallic dust particles in the nanomiter size range.
· Investigate aerogel samples, exposed to metal dusty plasma in a laboratory-size RF discharge device utilizing different metallic electrodes (mainly W, Fe, Ni, Mo, and Cu).
· Perform SEM analysis of the aerogel samples.
· Collect metal dust by aerogels exposed to different operation plasma regimes in FTU and evaluate the metal dust particle size and velocity distributions in different heat load condition on the machine walls.
ENEA_CNR
0.40
0.00
0.00
WP10-PWI-03-03-01/ENEAFRA/BS
Dust and plasma operation
· Perform dust characterization by silica aerogels in the FTU full-metallic tokamak. an Analysis of metallic dust collected by aerogels operating in different plasma regimes, both in ohmic discharges and in the presence of RF heating.
· Evaluate metal dust particle size and velocity distributions in the presence of different heat loads on the walls.
ENEA_Frascati
0.32
0.00
0.00
WP10-PWI-03-01-01/FOMRIJN/BS
Dust generation modelling
· Validation of dust creation codes:
· Investigation of the influence of ion-neutral reactions on the formation of large molecules, especially polycyclic aromatic hydrocarbons (PAH’s)
FOM_Rijnhuizen
0.20
0.00
0.00
WP10-PWI-03-01-01/FZJ/BS
Dust generation in present devices
· Application of laser ablation to damage the topmost layer of W and to release W dust into the TEXTOR edge plasma.
· Comparison of the ablated dust with re-launched W dust
· Studies of dust transport by a fast CCD camera and tests of the use of W interference filters.
FZJ
0.70
0.00
0.00
WP10-PWI-03-02-01/FZJ/BS
Conversion of co-deposits to dust
· Studies of connection between gross erosion at the ALT limiter and the measured net erosion and deposition on the tiles by post mortem analysis.
· Investigation of correlation of flaked layers (converting into dust particles).
· Post mortem analysis of the flaked particles concerning the fuel content by different techniques.
FZJ
0.30
0.00
0.00
WP10-PWI-03-03-01/FZJ/BS
Studies of dust mobilization, motion and impact on the core and edge plasma
· Perform experiments with different types of carbon and tungsten dust studying the mechanisms of dust mobilization, physics and the main processes leading to dust motion and dust concentrations in the core and edge plasmas.
· Application of specially designed holders for introduction of dust into TEXTOR plasmas.
· Detection of dust launch by means of high resolution and fast cameras and spectrometers. Application of Thomson scattering system for evaluation of the dust number density in plasmas.
· Assessment of dust size and the temperature of dust particles.
· Application of aerogel collectors to investigate the density and size distribution of dust particles and evaluate their velocities.
FZJ
0.35
0.00
0.00
WP10-PWI-03-03-03/FZJ/PS
Studies of dust mobilization, motion and impact on the core and edge plasma
· Perform experiments with different types of carbon and tungsten dust studying the mechanisms of dust mobilization, physics and the main processes leading to dust motion and dust concentrations in the core and edge plasmas.
· Application of specially designed holders for introduction of dust into TEXTOR plasmas.
· Detection of dust launch by means of high resolution and fast cameras and spectrometers. Application of Thomson scattering system for evaluation of the dust number density in plasmas.
· Assessment of dust size and the temperature of dust particles.
· Application of aerogel collectors to investigate the density and size distribution of dust particles and evaluate their velocities.
FZJ
0.00
0.25
7.00
WP10-PWI-03-01-01/IPP/BS
Focussed ion beam analysis of dust particle structures
· Analyses of individual dust particles from different devices (such as ASDEX Upgrade, TEXTOR, Tore Supra) by scanning electron microscopy assisted by focused ion beam cutting regarding their inner morphology and composition.
· Investigations of dust formation process and the growth of the particles.
IPP
0.80
0.00
0.00
WP10-PWI-03-01-02/IPP/PS
Focussed ion beam analysis of dust particle structures
· Analyses of individual dust particles from different devices (such as ASDEX Upgrade, TEXTOR, Tore Supra) by scanning electron microscopy assisted by focused ion beam cutting regarding their inner morphology and composition.
· Investigations of dust formation process and the growth of the particles.
· Commissioning of automatisation tool to increase the number of particles analysed in respect to their composition in order to enhance the statistical relevance of the obtain data.
IPP
0.00
0.10
0.00
WP10-PWI-03-03-01/IPP/PS
Dust and plasma operation
· Studies of the dust production in AUG by fast cameras and collection of dust after the campaign.
· Perform the reconstruction of dust trajectories in AUG with the help of second camera which will be installed (supplied by the F.Brochard (Univ. Nancy).
· Fast camera observations of arcs in AUG.
· Collection of dust by Si wafers and dust characterization d by SEM, EDX, FIB.
· Update the Helios device (FIB) with new data acquisition software in order to enable statistical more accurate measurements.
· Collection of dust at AUG by the filtered vacuum technique
· Perform a survey of the dust particles collected in AUG.
· Studies of the influence of dust events, observed by the camera systems, on the plasma performance.
IPP
0.00
0.20
10.00
WP10-PWI-03-03-04/IPP/BS
Dust and plasma operation in ASDEX Upgrade
Perform camera observations (fast and standard) to identify dust events and compare them to the plasma performance.
IPP
0.50
0.00
0.00
WP10-PWI-03-01-01/IPPLM/BS
Dust generation in present devices
· Characterization of dust collected in EU machines (AUG and TEXTOR): TEM, SEM, XPS, AES, BET etc. The special emphasis will be put on dust size, morphology, composition and internal structure.
· Characterization of the dust samples from AUG: plasma produced dust, captured by filtered vacuum collection with Teflon membranes with a pore size of 1 micron.
IPPLM_Poland
0.50
0.00
0.00
WP10-PWI-03-02-01/IPPLM/BS
Conversion of co-deposits to dust
· Collection of dust produced by ablation process with the use of two types of lasers (Nd:YAG or Yb:fiber). Studies of the dust production both in vacuum conditions and in gaseous atmosphere.
· Laboratory investigations of collected dust.
· Perform correlation of dust production rates with diagnostic outputs (LIBS, mass spectroscopy).
IPPLM_Poland
0.570
0.00
0.00
WP10-PWI-03-02-02/IPPLM/PS
Conversion of co-deposits to dust
· Collection of dust produced by ablation process with the use of two types of lasers (Nd:YAG or Yb:fiber). Studies of the dust production both in vacuum conditions and in gaseous atmosphere.
· Laboratory investigations of collected dust.
· Perform correlation of dust production rates with diagnostic outputs (LIBS, mass spectroscopy).
IPPLM_Poland
0.00
0.15
0.00
WP10-PWI-03-00/VR/PS
Leadership of the SEWG on Dust in Fusion Devices
Task coordinator of task agreement:
Dust generation and characterization in different devices, including the impact of fuel removal methods on dust production
VR
0.00
0.25
0.00
WP10-PWI-03-01-01/VR/BS
Dust generation in present devices
· Collection of dust in TEXTOR. Analysis of dust samples from different locations (floor, PFC surfaces, windows, liner) collected in TEXTOR. Comparison with dust from other machines; e.g. Tore Supra, ASDEX and with JET.
· Analysis of fuel content in dust from various locations. Comparison with dust generated by laser-induced co-deposit removal. Assessment of relation between dust structure and fuel content
VR
0.05
0.00
0.00
WP10-PWI-03-01-01/VR/PS
Dust generation in present devices
· Collection of dust in TEXTOR. Analysis of dust samples from different locations (floor, PFC surfaces, windows, liner) collected in TEXTOR. Comparison with dust from other machines; e.g. Tore Supra, ASDEX and with JET.
Analysis of fuel content in dust from various locations. Comparison with dust generated by laser-induced co-deposit removal. Assessment of relation between dust structure and fuel content
VR
0.00
0.15
5.00
WP10-PWI-03-01-02/VR/BS
Dust generation in present devices: Assessment of conversion deposits-to-dust
· Comparison of deposits on PFC and dust collected in TEXTOR in order to assess the conversion factor.
· Analysis of dust samples from different locations (floor, PFC surfaces, windows, liner) collected in TEXTOR.
· Comparison of global erosion in TEXTOR with the amount of generated dust. Multi-machine comparison
· Comparison, for various locations, of fuel content in dust and deposits.
· Comparison and assessment of dust generation by laser cleaning and oxidative methods.
VR
0.30
0.00
0.00
WP10-PWI-03-03-01/VR/BS
Characterization of mobile dust in plasma scrape-off layers using silica aerogel collectors
· Improve the exposure technique, through between shot optical microscopy for particle counting and thin surface over layers on collectors to facilitate the detection of small fast particles.
· Improve the post mortem analysis techniques, including 3D imaging of trapped particles and impact craters by nuclear microbeam, FIB SEM and tomography.
· Extend the database on intrinsic and injected dust fluxes in TEXTOR to a wider range of operating conditions and improved time resolution.
· Provide data to improve the understanding of dust transport and acceleration mechanisms by comparison of dust flow asymmetries in the TEXTOR and MAST tokamaks with those in the T2R reversed field pinch device.
· Investigate the role of hard terminations in T2R in dust production and mobilisation.
· Compare the behaviour of graphite and metal intrinsic dust through comparable dust collection in TEXTOR and MAST (with graphite walls) and T2R and FTU (metal walls).
VR
0.15
0.00
0.00
WP10-PWI-03-03-01/VR/PS
Characterization of mobile dust in plasma scrape-off layers using silica aerogel collectors
· Improve the exposure technique, through between shot optical microscopy for particle counting and thin surface overlayers on collectors to facilitate the detection of small fast particles.
· Improve the post mortem analysis techniques, including 3D imaging of trapped particles and impact craters by nuclear microbeam, FIB SEM and tomography.
· Extend the database on intrinsic and injected dust fluxes in TEXTOR to a wider range of operating conditions and improved time resolution.
· Provide data to improve the understanding of dust transport and acceleration mechanisms by comparison of dust flow asymmetries in the TEXTOR and MAST tokamaks with those in the T2R reversed field pinch device.
· Investigate the role of hard terminations in T2R in dust production and mobilisation.
· Compare the behaviour of graphite and metal intrinsic dust through comparable dust collection in TEXTOR and MAST (with graphite walls) and T2R and FTU (metal walls).
VR
0.00
0.30
0.00
Total
7.64
1.90
32.00
3.3 JET related activities
No JET related activities are meant to be implemented under this Task Agreement. JET related activities are implemented under EFDA Art.6. However some JET activities can be mentioned for information in this TA when they closely relate to the activity implemented under Art.5. JET data collected under the JET part of the EFDA WP can be brought together with other data under this TA when relevant for the progress of the work or used in multi- machine modelling activities under Art.5.
JET TF E and TF FT
· Observation of dust by visible and IR cameras
· Dust sampling during shutdowns (TF FT)
3.4 Publications
· EFDA 2009 Work Programme / EU PWI TF
· 2008 report of SEWG on Dust
4. Scientific and Technical Reports
4.1 Progress Reports
At the end of each calendar year, during the PWI TF annual meeting, the SEWG leader in charge of the task coordination shall present a report on all activities (under baseline and priority support) under the Task Agreement to the EFDA Leader for his approval. These reports shall integrate the progress made by each Association on each activity, and they shall indicate the level of achievement of the objectives, the situation of the activities, the allocation of resources and recommendations for the next year when applicable.
The EURATOM financial contribution will be made through the usual procedures for baseline support through the Contract of Association.
4.2 Report of achievements under Priority Support (final report and, when appropriate, intermediate reports)
In addition, achievement of Priority Support deliverables will be reported separately to the EFDA Leader. A final report shall be prepared by the SEWG leader in charge of the task coordination and submitted to the EFDA Leader. Each participating Association will have to report in one subsection on the degree to which the deliverables of their Tasks have been achieved and shall include a breakdown of expenditure. The Task Coordinator will collect the individual subsections into the final report for Priority Support activities addressing the associated milestones defined.
The EURATOM financial contribution will be made after approval of these reports by the EFDA Leader.
Table 4.1: Task Deliverables
Activity
Association
Priority Support Deliverables
Due Date
WP10-PWI-03-00/VR/PS
VR
Scientific report summarizing work within Task Agreement
31. Dec 2010
WP10-PWI-03-01-01/VR/PS
VR
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-03-01-02/IPP/PS
IPP
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-03-02-02/IPPLM/PS
IPPLM_Poland
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-03-03-01/CEA/PS
CEA
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-03-03-01/IPP/PS
IPP
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-03-03-01/VR/PS
VR
Scientific reports on performed tasks
31. Dec 2010
WP10-PWI-03-03-03/FZJ/PS
FZJ
Scientific reports on performed tasks
31. Dec 2010
4.3 Milestones
Mid 2010
SEWG Meeting: Collection and discussion of results obtained from the evaluation of experiments in 2009 and early